Touch display screen and display apparatus

ABSTRACT

The touch display screen includes a display panel, a touch electrode structure on a light-emitting side of the display panel and a bezel cover layer. The touch display screen includes a display area and a bezel area, and the bezel area has a protrusion sub-area toward the display area. The bezel cover layer is located in the bezel area. The touch electrode structure includes a plurality of touch electrodes and a plurality of leads. The plurality of touch electrodes are located in the display area, and the plurality of leads are arranged in the bezel area along an edge of the display area. The portion of each of the plurality of leads adjacent to the protrusion sub-area is a preset lead portion. An orthographic projection of the bezel cover layer on the display panel covers an orthographic projection of at least one the preset lead portion on the display panel.

CROSS REFERENCE TO RELATED APPLICATIONS

This disclosure is based on and claims priority under 35 U.S.C. 119 toChinese Patent Application No. 202110177347.3, filed on Feb. 7, 2021, inthe China National Intellectual Property Administration. The entiredisclosure of the above application is incorporated herein by reference.

FIELD

The disclosure relates to the field of display technology, in particularto a touch display screen and a display apparatus.

BACKGROUND

With rapid development of the display technology, touch screen panelsare widely used in people's lives. At present, the touch screen panelincludes an add on mode touch panel, an on cell touch panel and an incell touch panel for different structures. The on cell touch panel iswidely used in an organic light emitting diode (OLED) touch product,which facilitates the product thinning. Due to limit of productrequirements of flexible folding, a narrow bezel and the like, the OLEDtouch product usually adopts a flexible multi-layer on cell (FMLOC)process to design a touch structure. The FMLOC process refers to that ametal mesh electrode layer is fabricated on an encapsulation layer of adisplay panel for touch control. The add on mode touch panel is notneeded for this process. By means of the process, a screen thickness canbe reduced, so that folding is facilitated; and there is no attachmenttolerance, and a bezel width can be reduced.

SUMMARY

Embodiments of the disclosure provide a touch display screen and adisplay apparatus.

In one aspect, embodiments of the disclosure provide a touch displayscreen. The touch display screen includes a display panel, a touchelectrode structure on a light-emitting side of the display panel and abezel cover layer. The touch display screen includes a display area anda bezel area, and the bezel area has a protrusion sub-area toward thedisplay area. The bezel cover layer is located in the bezel area. Thetouch electrode structure includes a plurality of touch electrodes and aplurality of leads. The plurality of touch electrodes are located in thedisplay area, and the plurality of leads are arranged in the bezel areaalong an edge of the display area. The portion of each of the pluralityof leads adjacent to the protrusion sub-area is a preset lead portion.An orthographic projection of the bezel cover layer on the display panelcovers an orthographic projection of at least one of the preset leadportions on the display panel.

In another aspect, embodiments of the disclosure provide a displayapparatus, including a circuit board a touch display screen. The touchdisplay screen includes a display panel, a touch electrode structure ona light-emitting side of the display panel and a bezel cover layer. Thetouch display screen includes a display area and a bezel area, and thebezel area has a protrusion sub-area toward the display area. The bezelcover layer is located in the bezel area. The touch electrode structureincludes a plurality of touch electrodes and a plurality of leads. Theplurality of touch electrodes are located in the display area, and theplurality of leads are arranged in the bezel area along an edge of thedisplay area. The portion of each of the plurality of leads adjacent tothe protrusion sub-area is a preset lead portion. An orthographicprojection of the bezel cover layer on the display panel covers anorthographic projection of at least one of the preset lead portions onthe display panel. The circuit board is configured to drive the touchdisplay screen to work.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic structural diagram of a touch display screen.

FIG. 2 shows a schematic structural diagram of a touch display screenaccording to embodiments of the disclosure.

FIG. 3 shows an example first partial structure of a touch displayscreen according to embodiments of the disclosure.

FIG. 4 shows a schematic structural diagram of a touch structure in atouch display screen according to embodiments of the disclosure.

FIG. 5 shows an example second partial structure of a touch displayscreen according to embodiments of the disclosure.

FIG. 6 shows a schematic structural diagram of a display panel in atouch display screen according to embodiments of the disclosure.

FIG. 7 shows a sectional view of a display panel in an AA′ directionshown in FIG. 6 .

FIG. 8 shows a schematic diagram of inclination angles of upper surfacesof preset lead portions in different positions of an edge slope of anencapsulation layer in a touch display screen according to embodimentsof the disclosure.

FIG. 9 shows another schematic structural diagram of preset leadportions in different positions of an edge slope of an encapsulationlayer in a touch display screen according to embodiments of thedisclosure.

FIG. 10 shows yet another schematic diagram of positions of preset leadportions in different positions of an edge slope of an encapsulationlayer in a touch display screen according to embodiments of thedisclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In order to make objectives, features and advantages of the disclosureclearer and more understandable, the disclosure will be furtherdescribed in combination with accompanying drawings and embodiments.However, exemplary implementations can be implemented in various modesinstead of being constructed as being limited to the implementationsdescribed herein. Rather, these provided implementations are used forillustration, and the concept of the exemplary implementations iscomprehensively conveyed those skilled in the art. Same referencenumbers in the drawings represent same or similar structures, and thusrepeated descriptions will be omitted. Words for expressing positionsand directions described herein make description by taking the drawingsfor example and can be changed as required, and the changes fall in theprotection scope of the disclosure. The drawings of the disclosure areonly intended to illustrate a relative position relation rather than atrue scale.

It needs to be noted that the following description sets forth specificdetails so as to fully understand the disclosure. The disclosure can beimplemented in various other modes different from the modes describedherein, and those skilled in the art can make similar popularizationwithout departing from the intension of the disclosure. Therefore, thedisclosure is not limited by the specific implementations disclosedbelow. The subsequent description in the description is preferredimplementations for implementing the disclosure, but is only intended toexplain a general principle of the disclosure instead of limiting thescope of the disclosure. The protection scope of the disclosure isdefined by the appended claims.

A full screen, compared with a common display screen, can greatlyimprove a visual effect of a viewer with its larger screen-to-body ratioand an ultra-narrow bezel, thereby being of wide interest. Currently, ina display apparatus like a mobile phone using the full screen, in orderto realize the functions of taking a selfie, making a video call andperforming fingerprint recognition, a front camera, a telephonereceiver, a fingerprint recognition region or real keys, etc. areusually arranged in the front of the display apparatus.

In FIG. 1 , an OLED touch display screen for full screen display,generally includes a display area A1 and a bezel area B1. The bezel areaB1 has a protrusion sub-area B10 towards to the display area A1 to allowthe display area to have a notch. A camera 01, a telephone receiver 02and other devices are arranged in the protrusion sub-area B10. A touchstructure is located in the display area. However, due to highreflectivity of a metal layer in the touch structure, an anti-reflectionpolarizer of the OLED touch display screen cannot meet a full-viewrequirement. Especially, an anti-reflection effect in an oblique azimuthangle direction is modest, Mura often occurs at an edge of the Notchsub-area B10 due to the metal layer in the touch structure at certainviewing angles, and consequently, a display effect is affected.

At least for the above, embodiments of the disclosure provide a touchdisplay screen and a display apparatus, which are described below incombination with the drawings.

As shown in FIG. 2 and FIG. 3 , FIG. 2 is a schematic structural diagramof a touch display screen according to embodiments of the disclosure,and FIG. 3 is a schematic diagram of a partial structure of a touchdisplay screen according to embodiments of the disclosure. A touchdisplay panel according to embodiments of the disclosure includes adisplay panel (not shown in FIG. 2 and FIG. 3 ), a touch electrodestructure formed on a light-emitting side of the display panel and abezel cover layer 30 disposed on a side of the touch electrode structurefacing away from the display panel. The touch display screen includes adisplay area A1 and a bezel area B1, and the bezel area B1 has aprotrusion sub-area B10 toward the display area A1, the protrusionsub-area B10 making the display area have a notch. The bezel cover layer30 is located in the bezel area B1. The touch electrode structureincludes a plurality of touch electrodes (Tx and Rx) and a plurality ofleads 21. The plurality of touch electrodes (Tx and Rx) are located inthe display area A1, and the plurality of leads 21 are in the bezel areaB1 along the edge of the display area A1. The portions, of the leads 21,adjacent to the protrusion sub-area B10 are referred to as preset leadportions S1. An orthographic projection of the bezel cover layer 30 onthe display panel covers an orthographic projection of at least one ofthe preset lead portions S1 on the display panel.

Taking two leads 21 in FIG. 3 for example, the orthographic projectionof the bezel cover layer 30 on the display panel covers the orthographicprojection of the preset lead portion S1 closer to the upper side of thescreen on the display panel, but does not cover the orthographicprojection of the preset lead portion S1 further to the upper side ofthe screen on the display panel.

According to the touch display screen provided by the embodiments of thedisclosure, the orthographic projection of the bezel cover layer 30 onthe display panel covers an orthographic projection of at least one ofthe preset lead portions S1 on the display panel. That is, at least oneof the preset lead portions is covered with the bezel cover layer. Assuch, a reflection area of the leads is reduced, and the phenomenon ofMura at an edge of the protrusion sub-area is relieved.

In some embodiments, the preset lead portions of the leads can bearranged below without changing an area size of the bezel cover layer,so that an appearance of a touch display screen is not affected.

In some embodiments, as shown in FIG. 4 , the plurality of touchelectrodes include a plurality of touch driving electrodes Tx and aplurality of touch inductive electrodes Rx intersecting with theplurality of touch driving electrodes Tx. In some embodiments, theplurality of touch driving electrodes Tx extend in a row direction andare arranged in a column direction, and the plurality of touch inductiveelectrodes Rx extend in a column direction and are arranged in a rowdirection. Alternatively, the plurality of touch driving electrodes Txextend in a column direction and are arranged in a row direction, andthe plurality of touch inductive electrodes Rx extend in a row directionand are arranged in a column direction. The specific arrangement is notlimited herein. The plurality of leads include a plurality of touchleads 21 a correspondingly connected with the plurality of touchelectrodes and a ground lead 21 b, wherein the touch leads 21 a areconfigured to provide a driving signal for the corresponding touchelectrodes or receive an inductive signal on the corresponding touchelectrodes, and the ground lead 21 b is configured to be anti-static.

In some embodiments, the protrusion sub-area B10 may be located at a topof the touch display screen, that is, the protrusion sub-area B10 islocated at a top side of the display area A1. Alternatively, theprotrusion sub-area may be located at other positions of the touchdisplay screen, and a position of the protrusion sub-area is not limitedherein.

Exemplarily, as shown in FIG. 4 , taking the sub-area B10 located at thetop side of the display area A1, the plurality of touch drivingelectrodes Tx extending in the row direction and arranged in the columndirection, and the plurality of touch inductive electrodes Rx generallyextending in the column direction and arranged in the row direction forexample, the touch leads 21 a connected with the touch drivingelectrodes Tx are arranged along a right edge of the display area A1,the touch leads 21 a connected with the touch inductive electrodes Rxare arranged along an upper edge, a left edge and a lower edge of thedisplay area, and the ground lead 21 b is arranged around the edge ofthe display area A1. As the leads are made of a metal material, in therelated art, at the edge of the protrusion sub-area B10, the phenomenonof Mura often occurs due to reflection of the metal leads.

For the sake of convenient description, in the disclosure, the portionsof the leads adjacent to the protrusion sub-area B10 are defined as thepreset lead portions. That is, the portions of the leads causing thephenomenon of Mura at the edge of the protrusion sub-area are the presetlead portions. For example, in FIG. 4 , the ground lead 21 b has theportion adjacent to the protrusion sub-area B10, the touch leads 21 aconnected with the touch inductive electrodes Rx have the portionsadjacent to the protrusion sub-area B10, so that in the disclosure, theground lead 21 b and at least part of the touch leads 21 a have thepreset lead portions S1 adjacent to the protrusion sub-area B10. In FIG.4 , for example, the plurality of preset lead portions S1 include: apreset lead portion of the ground lead 21 b and the preset lead portionsof the touch leads 21 a connected with the touch inductive electrodesRx.

It can be understood that not all the leads have the preset leadportions, and only the leads adjacent to the protrusion sub-area havethe preset lead portions.

In the disclosure, the preset lead portions in the leads are set belowthe bezel cover layer, without increasing an area of the bezel coverlayer. That is, at least one of the preset lead portions is covered withthe bezel cover layer. Thus a reflection area at the edge of theprotrusion sub-area is reduced, and then the phenomenon of Mura at theedge of the protrusion sub-area is relieved.

In some embodiments, the orthographic projection of the bezel coverlayer covers orthographic projections of all the preset lead portions.Exemplarily, the bezel cover layer covers all the preset lead portions,so that the phenomenon of Mura at the edge of the protrusion sub-area isrelieved as much as possible.

In some embodiments, a camera, a telephone receiver and other devicesmay be generally arranged in the protrusion sub-area. In the case thatall the preset lead portions are set below the bezel cover layer, if thequantity of the preset lead portions is too large, arrangement oforiginal devices in the protrusion sub-area may be affected, so that thequantity of the preset lead portions below the bezel cover layer may bedesigned according to an actual product.

In the case that the bezel cover layer cannot cover all the preset leadportions, a line width of each of the preset lead portions not coveredwith the bezel cover layer may be reduced, so that the reflection areaof the metal at the edge of the protrusion sub-area may be reduced asmuch as possible.

Exemplarily, as shown in FIG. 5 , in the touch display screen providedby the embodiments of the disclosure, the quantity of the plurality ofpreset lead portions S1 is N, and the N preset lead portions S1 arearranged in sequence in a direction X from the display area A1 to theprotrusion sub-area B10.

Among the N preset lead portions S1, the orthographic projection of thebezel cover layer 30 on the display panel covers orthographicprojections of x preset lead portions S1 on the display panel, where xis an integer larger than or equal to 1 but smaller than N. FIG. 5 makesillustration by taking N=4 and x=3 for example.

The (N-x) preset lead portions S1 with orthographic projections on thedisplay panel not covered by the orthographic projection of the bezelcover layer 30 on the display panel are first preset lead portions S10.That is, the first preset lead portions S10 are the preset lead portionsS1 not covered with the bezel cover layer 30. A wire width of each ofthe first preset lead portions S10 is smaller than a wire width of theother portion, except the first preset lead portion S10, of the lead 21which the first preset lead portion S10 belongs to. That is, by reducingthe wire width of the first preset lead portions S10 not covered withthe bezel cover layer 30 at the edge in the protrusion sub-area, thearea of the leads at the edge of the protrusion sub-area is reduced, andthus the phenomenon of Mura at the edge of the protrusion sub-area isreduced. In some embodiments, only the widths of the preset leadportions S1 in the leads are reduced, a wire width of the other portionsof the leads 21 is not changed, and thus the influence on resistance ofthe leads 21 may be reduced as much as possible.

It can be understood that the wire width of each of the first presetlead portions S10 is smaller than the wire width of the other portion,except the first preset lead portion S10, of the lead 21 which the firstpreset lead portion S10 belongs to. Exemplarily, taking one lead forexample, as shown in FIG. 5 , the wire width of the first preset leadportion S10 of the lead 21 is reduced, wire widths of the other portionsof the lead 21 are larger than the wire width of the first preset leadportion S10.

In some embodiments, the disclosure does not limit the wire width ofeach first preset lead portion, and the wire width of the first presetlead portion may be reduced as much as possible in a range of meetingthe requirement for the resistance of the leads.

Exemplarily, in some embodiments, a wire width of each touch lead isusually 30 μm, a width of the first preset lead portion of the touchlead may be set to be smaller than or equal to 20 μm; a wire width ofthe ground lead is usually 100 μm, a width of the first preset leadportion of the ground lead may be set to be smaller than or equal to 30μm. Specific setting may be made according to an actual product.

In some embodiments, the wire width of each touch lead is smaller thanthe wire width of the ground lead, reduction of a wire width of aportion of the ground lead has smaller influence on whole resistance ofthe ground lead. As such, the preset lead portion of the ground lead maybe arranged at one side close to the display area.

In some embodiments, the x preset lead portions with orthographicprojections on the display panel covered by the orthographic projectionof the bezel cover layer belong to the touch leads respectively.

Furthermore, the orthographic projection of the bezel cover layer on thedisplay panel covers an orthographic projection of each preset leadportion belonging to the corresponding touch lead on the display panel,that is, the bezel cover layer covers the preset lead portion of eachtouch lead.

In some embodiments, as shown in FIG. 6 and FIG. 7 , in the touchdisplay screen provided by the embodiments of the disclosure, thedisplay panel 10 includes an OLED display substrate 11 and anencapsulation layer 12 on a light-emitting side of the OLED displaysubstrate 11. The display panel 10 has a notch in an area correspondingto the protrusion sub-area B10, a side surface of the encapsulationlayer 12 close to the protrusion sub-area B10 is a slope, and at leastpart of the preset lead portions S1 are disposed on the slope. Thepreset lead portions S1 are disposed on the slope so that a bezel widthof the display panel 10 may be reduced.

In some embodiments, as shown in FIG. 7 , the OLED display substrate 11includes a base 111 and a display function layer 112 disposed on thebase 111. The display function layer 112 generally includes a pixelcircuit array and an OLED array disposed on the pixel circuit array, andthe encapsulation layer 12 covers the display function layer 112. Thesurface of the encapsulation layer 12 has a inclination angle at theedge of the protrusion sub-area, that is, a side surface of theencapsulation layer at the edge of the protrusion sub-area is a sloperelative to a plane where the base is located. At least part of leads inthe touch electrode structure are disposed on the slope. Due toexistence of a corner of the protrusion sub-area, a slope of theencapsulation layer at the corner is steeper than slopes in the otherpositions of the encapsulation layer. As such, slope steep degrees ofthe slopes of the encapsulation layer in different positions aredifferent, consequently, slope angles in the different positions withthe leads thereon are inconsistent, thus inclination angles of metalreflection surfaces of the same lead in the different positions aredifferent. As shown in FIG. 8 , for example, the inclination angle θ ofthe metal reflection surface of the preset lead portion S1 on the slopein the position N is smaller than the inclination angle θ of the metalreflection surface of the preset lead portion S1 on the slope in theposition M in FIG. 6 , and consequently, the phenomenon of Mura at theedge of the protrusion sub-area occurs.

In some embodiments, in the touch display screen provided by theembodiments of the disclosure, as for the preset lead portions disposedon the slopes and not covered by the bezel cover layer, an includedangle between an upper surface of the side of each preset lead portionfacing away from the display substrate and a base surface of the OLEDdisplay substrate 11 is within a preset range, so that angles of thereflection surfaces of the same preset lead portion in the differentpositions are consistent as much as possible. In order to guarantee thatthe angles of the reflection surfaces of the same preset lead portion inthe different positions are consistent as much as possible, as shown inFIG. 9 , a thickness of the preset lead portion S1 may be non-uniform,for example, a thickness of a part of the preset lead portion S1 closeto a top of the encapsulation layer 12 in the position M may be reduced,or a thickness of a part of the preset lead portion S1 close to a bottomof the encapsulation layer 12 in the position N may be reduced.

In some embodiments, in the touch display screen provided by theembodiments of the disclosure, as for the preset lead portions disposedon the slopes, along an extending direction of each preset lead portion,an included angle between a surface of the preset lead portion in directcontact with the slope and the base surface of the OLED displaysubstrate is within a preset range, that is, slope angles of the samepreset lead portion on different positions are consistent as much aspossible. As shown in FIG. 10 , in order to make the slope angles of thesame preset lead portion on different positions consistent as much aspossible, the preset lead portion S1 on the position M may betransferred from the position indicated by a dotted box (a positionshown in FIG. 8 ) towards the top of the encapsulation layer 12, thus anincluded angle between a surface of the preset lead portion S1 on theposition N in direct contact with the slope and the base surface of theOLED display substrate and an included angle between a surface of thepreset lead portion S1 on the position M in direct contact with theslope and the base surface of the OLED display substrate each is withina preset range, that is, they are consistent as much as possible.

Based on the same inventive concept, embodiments of the disclosureprovide a display apparatus, including any one display device accordingto embodiments of the disclosure. The display apparatus may include: amobile phone, a tablet PC, a television, a display, a laptop, a digitalphoto frame, a navigator and any product or part with a displayfunction. Implementation of the display apparatus may be referred toembodiments of the display panel, and repetitions are omitted.

According to the touch display screen and the display apparatus providedby the embodiments of the disclosure, the touch display screen includesthe display panel, the touch electrode structure on the light-emittingside of the display panel and the bezel cover layer disposed on the sideof the touch electrode structure facing away from the display panel. Thetouch display screen includes the display area and the bezel area, andthe bezel area has the protrusion sub-area toward the display area. Thebezel cover layer is located in the bezel area. The touch electrodestructure includes the plurality of touch electrodes and the pluralityof leads. The plurality of touch electrodes are located in the displayarea, and the plurality of leads are arranged in the bezel area alongthe edge of the display area. The portion of each of the plurality ofleads adjacent to the protrusion sub-area is the preset lead portion.The orthographic projection of the bezel cover layer on the displaypanel covers an orthographic projection of at least one of the presetlead portions on the display panel. That is, at least one of the presetlead portions is covered with the bezel cover layer. As such, areflection area of the leads is reduced, and thus the phenomenon of Muraat the edge of the protrusion sub-area is relieved.

Apparently, those skilled in the art can make various changes andmodifications for the disclosure without departing from the spirit andscope of the disclosure. In this case, if these changes andmodifications of the disclosure fall in the scope of the claims andtheir equivalents, the disclosure also intends to include these changesand modifications.

What is claimed is:
 1. A touch display screen, comprising: a displaypanel; a touch electrode structure on a light-emitting side of thedisplay panel; and a bezel cover layer disposed on a side of the touchelectrode structure facing away from the display panel; wherein thetouch display screen has a display area and a bezel area, and the bezelarea has a protrusion sub-area toward the display area; the bezel coverlayer is located in the bezel area; the touch electrode structurecomprises a plurality of touch electrodes and a plurality of leads,wherein the plurality of touch electrodes are located in the displayarea, and the plurality of leads are arranged in the bezel area along anedge of the display area; a portion of each of the plurality of leadsadjacent to the protrusion sub-area is a preset lead portion; anorthographic projection of the bezel cover layer on the display panelcovers an orthographic projection of at least one of the preset leadportions on the display panel; a quantity of preset lead portions is N,and the N preset lead portions are arranged in sequence in a directionfrom the display area to the protrusion sub-area; wherein N is aninteger larger than or equal to 2; among the N preset lead portions, theorthographic projection of the bezel cover layer on the display panelcovers an orthographic projection of x preset lead portions on thedisplay panel, wherein x is an integer larger than or equal to 1 butsmaller than N; and each of (N-x) preset lead portions with anorthographic projection on the display panel not covered by theorthographic projection of the bezel cover layer on the display panel isa first preset lead portion, and a wire width of each first preset leadportion is smaller than a wire width of other portion, except the firstpreset lead portion, of a lead which the each first preset lead portionbelongs to.
 2. The touch display screen according to claim 1, whereinthe plurality of leads comprise a ground lead and a plurality of touchleads connected with the plurality of touch electrodes; the ground leadand at least part of the touch leads have the preset lead portions; andthe x preset lead portions each belongs to a touch lead.
 3. The touchdisplay screen according to claim 2, wherein the orthographic projectionof the bezel cover layer on the display panel covers each preset leadportion belonging to a touch lead.
 4. The touch display screen accordingto claim 2, wherein a preset lead portion of the ground lead is a firstpreset lead portion, and a wire width of the first preset lead portionis smaller than or equal to 30 μm.
 5. A display apparatus, comprising acircuit board and a touch display screen; wherein the touch displayscreen comprises: a display panel; a touch electrode structure on alight-emitting side of the display panel; and a bezel cover layerdisposed on a side of the touch electrode structure facing away from thedisplay panel; wherein the touch display screen has a display area and abezel area, and the bezel area has a protrusion sub-area toward thedisplay area; the bezel cover layer is located in the bezel area; thetouch electrode structure comprises a plurality of touch electrodes anda plurality of leads, wherein the plurality of touch electrodes arelocated in the display area, and the plurality of leads are arranged inthe bezel area along an edge of the display area; a portion of each ofthe plurality of leads adjacent to the protrusion sub-area is a presetlead portion; an orthographic projection of the bezel cover layer on thedisplay panel covers an orthographic projection of at least one of thepreset lead portions on the display panel; a quantity of preset leadportions is N, and the N preset lead portions are arranged in sequencein a direction from the display area to the protrusion sub-area; whereinN is an integer larger than or equal to 2; among the N preset leadportions, the orthographic projection of the bezel cover layer on thedisplay panel covers an orthographic projection of x preset leadportions on the display panel, wherein x is an integer larger than orequal to 1 but smaller than N; and each of (N-x) preset lead portionswith an orthographic projection on the display panel not covered by theorthographic projection of the bezel cover layer on the display panel isa first preset lead portion, and a wire width of each first preset leadportion is smaller than a wire width of other portion, except the firstpreset lead portion, of a lead which the each first preset lead portionbelongs to; and wherein the circuit board is configured to drive thetouch display screen to work.
 6. The display apparatus according toclaim 5, wherein the plurality of leads comprise one ground lead and aplurality of touch leads connected with the plurality of touchelectrodes; the ground lead and at least part of the touch leads havethe preset lead portions; and the x preset lead portions each belongs toa touch lead.
 7. The display apparatus according to claim 6, wherein theorthographic projection of the bezel cover layer on the display panelcovers each preset lead portion belonging to a touch lead.
 8. Thedisplay apparatus according to claim 6, wherein a preset lead portion ofthe ground lead is a first preset lead portion, and a wire width of thefirst preset lead portion is smaller than or equal to 30 μm.
 9. A touchdisplay screen, comprising: a display panel; a touch electrode structureon a light-emitting side of the display panel; and a bezel cover layerdisposed on a side of the touch electrode structure facing away from thedisplay panel; wherein the touch display screen has a display area and abezel area, and the bezel area has a protrusion sub-area toward thedisplay area; the bezel cover layer is located in the bezel area; thetouch electrode structure comprises a plurality of touch electrodes anda plurality of leads, wherein the plurality of touch electrodes arelocated in the display area, and the plurality of leads are arranged inthe bezel area along an edge of the display area; a portion of each ofthe plurality of leads adjacent to the protrusion sub-area is a presetlead portion; an orthographic projection of the bezel cover layer on thedisplay panel covers an orthographic projection of at least one of thepreset lead portions on the display panel; the display panel comprisesan Organic Light Emitting Diode (OLED) display substrate and anencapsulation layer disposed on a light-emitting side of the OLEDdisplay substrate; the display panel comprises a notch in an areacorresponding to the protrusion sub-area; and a side surface of theencapsulation layer close to the protrusion sub-area is a slope, and atleast part of the preset lead portions are disposed on the slope. 10.The touch display screen according to claim 9, wherein for preset leadportions disposed on the slope and with orthographic projections on thedisplay panel not covered by the orthographic projection of the bezelcover layer on the display panel, an included angle between an uppersurface of a side of each of said preset lead portions facing away fromthe display panel and a base surface of the OLED display substrate iswithin a preset range.
 11. The touch display screen according to claim10, wherein for said preset lead portions disposed on the slope, alongan extending direction of each of said preset lead portions, an includedangle between a surface of each of said preset lead portions in directcontact with the slope and the base surface of the OLED displaysubstrate is within a preset range.
 12. A display apparatus, comprisinga circuit board and the touch display screen according to claim 9;wherein the circuit board is configured to drive the touch displayscreen to work.
 13. The display apparatus according to claim 12, whereinfor preset lead portions disposed on the slope and with orthographicprojections on the display panel not covered by the orthographicprojection of the bezel cover layer on the display panel, an includedangle between an upper surface of a side of each of said preset leadportions facing away from the display panel and a base surface of theOLED display substrate is within a preset range.
 14. The displayapparatus according to claim 13, wherein for said preset lead portionsdisposed on the slope, along an extending direction of each of saidpreset lead portions, an included angle between a surface of each ofsaid preset lead portions in direct contact with the slope and the basesurface of the OLED display substrate is within a preset range.